Small peptides inhibit gut trypsin‐like proteases and impair<i>Anticarsia gemmatalis</i>(<scp>L</scp>epidoptera:<scp>N</scp>octuidae) survival and development

Barros, Rafael de Almeida; Meriño‐Cabrera, Yaremis; Vital, Camilo Elber; Junior, Neilier; Oliveira, Cauê Neves de; Barbosa, Samuel Lessa; Assis, João Victor Marques Gonçalves; Oliveira, Humberto Josué Ramos de; Oliveira, Maria Goreti de Almeida

doi:10.1002/ps.6191

Cited by 10 publications

(2 citation statements)

References 55 publications

(95 reference statements)

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“…On the other hand, in silico tools have recently become an unavoidable approach for the optimization of protein–protein complexes and the design of new molecules from the study of the interaction between these proteins related to pest management (de Almeida Barros, Meriño‐Cabrera, Severiche Castro, da Silva Junior, de Oliveira, et al, 2022; de Almeida Barros, Meriño‐Cabrera, Severiche Castro, da Silva Júnior, Schultz, et al, 2022; de Almeida Barros et al, 2021; Halim et al, 2022; Machado et al, 2020; Meriño‐Cabrera, de Oliveira Mendes, et al, 2020; Meriño‐Cabrera, Severiche Castro, et al, 2020; Meriño‐Cabrera, et al, 2022). Using tools such as molecular modeling of proteins, which allows us to determine the three‐dimensional (3D) structure of the sequences of receptors and ligands such as yam disocorins; protein–protein molecular docking, to determine the affinity site and energy of the inhibitor to the digestive enzymes of interest; and study of the interface using software such as Pymol and Discovery, which allow exploring inhibitory residues that bind to the active site of the enzyme and/or potential to reduce enzyme activity (hot‐spot residues), which would be expensive and slowly by experimental methods (Childers & Daggett, 2017); In addition, molecular dynamics (MD) simulations are performed to analyze the stability of the protein–protein complex and the free binding energy in aqueous solution estimation, allowing to understand several underlying biological phenomena, such as enzyme inhibition (Patel & Ytreberg, 2018).…”

Section: Introductionmentioning

confidence: 99%

Structural analysis and inhibition capacity of dioscorin protein yam: Theoretical study by molecular docking and dynamic simulations

Severiche‐Castro,

Wilches Diaz,

Combariza Montañez

et al. 2023

Arch Insect Biochem Physiol

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Proteases such as trypsins in the gut of Spodoptera frugiperda are responsible for breaking down dietary proteins into amino acids necessary for insect growth and development. In this study, we characterized the insecticidal potential of dioscorin, the storage protein of yam (Dioscorea alata), using molecular docking and molecular dynamics simulations to determine the interactions between trypsin enzymes and the protein inhibitor dioscorin. To achieve this, we used the three‐dimensional structures of the trypsin‐like digestive enzymes of S. frugiperda, a pest of corn and cotton, as receptors or target molecules. We performed protein–protein docking using Cluspro software, estimation of the binding free energy, and information on the dynamic and time‐dependent behavior of dioscorin–trypsin complexes using the NAMD package. Our computational analysis showed that dioscorin can bind to the digestive trypsins of S. frugiperda, as confirmed by the affinity energy values (−1022.4 to −1236.9), stability of the complexes during the simulation trajectory, and binding free energy values between −57.3 and −66.9 kcal/mol. Additionally, dioscorin uses two reactive sites to bind trypsin, but the largest contribution to the interaction energy is made by amino acid residues between amino acid backbone positions 8–14 by hydrogen bonds, hydrophobic, and Van der Waals (VdW) interactions. VdW is the energy that makes the greatest contribution to the binding energy. Collectively, our findings demonstrate, for the first time, the binding capacity of the yam protein dioscorin to the digestive trypsin of S. frugiperda. These promising results suggest a possible bioinsecticide action of dioscorin.

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Section: Introductionmentioning

confidence: 99%

Structural analysis and inhibition capacity of dioscorin protein yam: Theoretical study by molecular docking and dynamic simulations

Severiche‐Castro,

Wilches Diaz,

Combariza Montañez

et al. 2023

Arch Insect Biochem Physiol

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“…Many natural peptides and synthetic inhibitors of trypsin have an arginine or a lysine that binds in the specificity site of the enzyme, which is near the catalytic triad responsible for the catalysis (de Almeida Barros et al, 2021; Presnell et al, 1998). In particular, benzamidine, a structural mimic of arginine and itself a potent inhibitor (Mares‐Guia & Shaw, 1965), is the primary component of many larger inhibitors.…”

Section: Introductionmentioning

confidence: 99%

Extensive reprogramming of protein isoforms and histopathological alterations in the midgut of Anticarsia gemmatalis fed with protease inhibitors

Coura

Silva

Meriño‐Cabrera

et al. 2021

Annals of Applied Biology

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Protease inhibitors (PIs) interfere with digestion, leading to poor nutrient absorption and decreasing amino acid availability in insects. Ingestion of PIs can delay development, cause anatomical malformations, reduce fertility and change the set of proteases in the insect gut. This study evaluated the proteomic profile in the midgut of Anticarsia gemmatalis fed on synthetic (Berenil® with a bis‐benzamidine as active ingredient) and natural (SKTI) protease inhibitors and their effect on the gut physiology, proteolytic activity and the structural characteristics of the trypsin‐inhibitor binding. Larger numbers of protein isoforms were identified specially related to protease activity and stress processes, being that the synthetic PI triggered a lower reprogramming than SKTI. Furthermore, Berenil also promoted higher reduction on midgut protease activity at first times of PI treatment. Molecular modelling of the interactions between the identified proteases and PIs indicated that Berenil can interact with the trypsin enzymes and access to a more hydrophobic site promoting the inhibitory effect on serine proteases. Besides, its inhibitory capacity and structural damage on the midgut cells was sped up possibly by the delay in the expression of proteases, the reprogramming less extensive and the lower expression of upregulated isoforms. Thus, the integration of our results shows that the use of synthetic PIs, such as Berenil, can be efficient for the management of A. gemmatalis.

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Inhibition constant and stability of tripeptide inhibitors of gut trypsin‐like enzyme of the soybean pest Anticarsia gemmatalis

Barros

Meriño‐Cabrera

Castro

et al. 2022

Arch Insect Biochem Physiol

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Insects overcome the action of natural protease inhibitors (PIs) due to evolutionary adaptations through endogenous proteolysis and reprogramming proteases. Insect adaptations complicate the formulation of IP‐based crop protection products. However, small peptides designed based on the active site of enzymes have shown promising results that could change this scenario. GORE1 and GORE2 are designed tripeptides that reduce the survival of Anticarsia gemmatalis when ingested orally. In this article, the stability and ability of the peptides to bind trypsin‐like enzymes of A. gemmatalis were evaluated by molecular dynamics (MD) simulations. The ability of the peptides to inhibit trypsin‐like enzymes in vivo was compared with the SKTI protein by feeding A. gemmatalis larvae at different concentrations, followed by an inhibition persistence assay. During the MD simulation of enzyme–ligand complexes, both peptides showed a small variation of root‐mean‐square deviation and root‐mean‐square fluctuation, suggesting that these molecules reach equilibrium when forming a complex with the trypsin‐like enzyme. Furthermore, both peptides form hydrogen bonds with substrate recognition sites of A. gemmatalis trypsin‐like enzyme, with GORE2 having more interactions than GORE1. Larvae of A. gemmatalis exposed to the peptides and SKTI showed a similar reduction in proteolytic activity, but the persistence of inhibition of trypsin‐like enzyme was longer in peptide‐fed insects. Despite their size, the peptides exhibit important active and substrate binding site interactions, stability during complex formation, and steadiness effects in vivo. The results provide fundamental information for the development of mimetic molecules and help in decision‐making for the selection of delivery methods for larger‐scale experiments regarding similar molecules.

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Small peptides inhibit gut trypsin‐like proteases and impairAnticarsia gemmatalis(Lepidoptera:Noctuidae) survival and development

Cited by 10 publications

References 55 publications

Structural analysis and inhibition capacity of dioscorin protein yam: Theoretical study by molecular docking and dynamic simulations

Structural analysis and inhibition capacity of dioscorin protein yam: Theoretical study by molecular docking and dynamic simulations

Extensive reprogramming of protein isoforms and histopathological alterations in the midgut of Anticarsia gemmatalis fed with protease inhibitors

Inhibition constant and stability of tripeptide inhibitors of gut trypsin‐like enzyme of the soybean pest Anticarsia gemmatalis

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